The invention relates to an exposure apparatus and a method for projecting a charged particle beam onto a target. The exposure apparatus comprises a charged particle optical arrangement comprising a charged particle source for generating a charged particle beam and a charged particle blocking element and/or a current limiting element for blocking at least a part of a charged particle beam from a charged particle source. The charged particle blocking element and the current limiting element comprise a substantially flat substrate provided with an absorbing layer comprising Boron, Carbon or Beryllium. The substrate further preferably comprises one or more apertures for transmitting charged particles. The absorbing layer is arranged spaced apart from the at least one aperture.

A method for scanning a sample by a charged particle beam tool is provided. The method includes providing the sample having a scanning area including a plurality of unit areas, scanning a unit area of the plurality of unit areas, blanking a next unit area of the plurality of unit areas adjacent to the scanned unit area, and performing the scanning and the blanking the plurality of unit areas until all of the unit areas are scanned.

Inspection systems and methods are disclosed. An inspection system may include a first energy source configured to provide a first landing energy beam and a second energy source configured to provide a second landing energy beam. The inspection system may also include a beam controller configured to selectively deliver one of the first and second landing energy beams towards a same field of view, and to switch between delivery of the first and second landing energy beams according to a mode of operation of the inspection system.

A method for scanning a sample by a charged particle beam tool is provided. The method includes providing the sample having a scanning area including a plurality of unit areas, scanning a unit area of the plurality of unit areas, blanking a next unit area of the plurality of unit areas adjacent to the scanned unit area, and performing the scanning and the blanking the plurality of unit areas until all of the unit areas are scanned.

An ion implantation system, including an ion source, and a buncher to receive a continuous ion beam from the ion source, and output a bunched ion beam. The buncher may include a drift tube assembly, having an alternating sequence of grounded drift tubes and AC drift tubes. The drift tube assembly may include a first grounded drift tube, arranged to accept a continuous ion beam, at least two AC drift tubes downstream to the first grounded drift tube, a second grounded drift tube, downstream to the at least two AC drift tubes. The ion implantation system may include an AC voltage assembly, coupled to the at least two AC drift tubes, and comprising at least two AC voltage sources, separately coupled to the at least two AC drift tubes. The ion implantation system may include a linear accelerator, comprising a plurality of acceleration stages, disposed downstream of the buncher.

The invention relates to an exposure apparatus and a method for projecting a charged particle beam onto a target. The exposure apparatus comprises a charged particle optical arrangement comprising a charged particle source for generating a charged particle beam and a charged particle blocking element and/or a current limiting element for blocking at least a part of a charged particle beam from a charged particle source. The charged particle blocking element and the current limiting element comprise a substantially flat substrate provided with an absorbing layer comprising Boron, Carbon or Beryllium. The substrate further preferably comprises one or more apertures for transmitting charged particles. The absorbing layer is arranged spaced apart from the at least one aperture.

A measuring apparatus that irradiates a sample with a charged particle beam to observe the sample includes a particle source that outputs the charged particle beam, a lens that collects the charged particle beam, a detector that detects a signal of emitted electrons emitted from the sample which is irradiated with the charged particle beam, and a control device that controls the output of the charged particle beam and the detection of the signal of the emitted electrons in accordance with an observation condition, in which the control device sets, as the observation condition, a first parameter for controlling an irradiation cycle of the charged particle beam, a second parameter for controlling a pulse width of the pulsed charged particle beam, and a third parameter for controlling detection timing of the signal of the emitted electron within the irradiation time of the pulsed charged particle beam, and the third parameter is determined in accordance with a difference in intensity of signals of the plurality of the emitted electrons emitted from the irradiation position of the charged particle beam.

A method for scanning a sample by a charged particle beam tool is provided. The method includes providing the sample having a scanning area including a plurality of unit areas, scanning a unit area of the plurality of unit areas, blanking a next unit area of the plurality of unit areas adjacent to the scanned unit area, and performing the scanning and the blanking the plurality of unit areas until all of the unit areas are scanned.

A beam blanking device for a multi-beamlet charged particle beam apparatus is provided. The beam blanking device includes a first blanking unit, a second blanking unit and a third blanking unit. The first blanking unit includes a first blanking electrode and a first aperture. The second blanking unit includes a second blanking electrode and a second aperture. The third blanking unit includes a third blanking electrode and a third aperture. The beam blanking device includes a common electrode forming a first counter electrode for the first blanking electrode, a second counter electrode for the second blanking electrode and a third counter electrode for the third blanking electrode. The first blanking unit, the second blanking unit and the third blanking unit are arranged in a planar array and define a plane of the planar array. The first blanking electrode is arranged for generating a first electric field between the first blanking electrode and the common electrode in the first aperture for deflecting a first beamlet of the multi-beamlet charged particle beam apparatus into a first deflection direction. The second blanking electrode is arranged for generating a second electric field between the second blanking electrode and the common electrode in the second aperture for deflecting a second beamlet of the multi-beamlet charged particle beam apparatus into a second deflection direction. The third blanking electrode is arranged for generating a third electric field between the third blanking electrode and the common electrode in the third aperture for deflecting a third beamlet of the multi-beamlet charged particle beam apparatus into a third deflection direction. A dividing plane intersecting the planar array separates the first blanking unit from the second blanking unit and the third blanking unit, wherein the first deflection direction, the second deflection direction and the third deflection direction point away from the dividing plane.

Charged particle beams (CPBs) are modulated using a beam blanker/deflector and an electrically pulsed extraction electrode in conjunction with a field emitter and a gun lens. With such modulation, CPBs can provide both pulsed and continuous mode operation as required for a particular application, while average CPB current is maintained within predetermined levels, such as levels that promote X-ray safe operation. Either the extraction electrode or the beam blanker/deflector can define CPB pulse width, CPB on/off ratio, or both.